Recycling of coated electrode materials

ABSTRACT

Examples are disclosed of methods to recycle coated positive-electrode material of a lithium-ion battery. One example provides a method including relithiating the coated positive-electrode material in a solution comprising lithium ions, and after relithiating, separating the coated positive-electrode material from the solution. In some examples, coated positive-electrode materials may be reinstated using lower process temperatures than uncoated positive-electrode material.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent Application No. 62/632,847, filed Feb. 20, 2018, the entirety of which is hereby incorporated herein by reference for all purposes.

TECHNICAL FIELD

The present application relates to the field of lithium-ion batteries, and more particularly, to recycling coated positive-electrode material of a lithium-ion battery.

BACKGROUND

Lithium-ion batteries provide power to products ranging from automobiles to smart phones. These batteries are rechargeable over many cycles, tolerant to various environmental factors, and have a relatively long useful lifetime. Nevertheless, they eventually fail or are discarded prior to failure, and therefore contribute to a significant and growing waste stream. In view of this situation, environmental regulations, industry standards, and collection services have arisen to promote the recycling of lithium-ion batteries.

SUMMARY

Examples are disclosed of methods to recycle positive-electrode material of a lithium-ion battery. One example provides a method including relithiating the positive-electrode material in a solution comprising lithium ions and an oxidizing agent, and after relithiating, separating the positive-electrode material from the solution.

BRIEF DESCRIPTION OF THE DRAWING

FIG. 1 illustrates an example method to recycle a lithium-ion battery in accordance with an embodiment of this disclosure.

FIG. 2 shows a plot of X-ray powder diffraction patterns for example NCA electrode materials.

FIG. 3 shows a plot of specific capacity of first charge-discharge cycle for an example hydrothermally treated recycled NCA electrode material compared to an untreated NCA standard electrode material.

FIG. 4 shows a plot of X-ray powder diffraction patterns for additional example NCA electrode materials.

FIG. 5 shows a graph of specific capacity as a function of charge-discharge cycle number for an example untreated NCA standard electrode material.

FIG. 6 shows a graph of specific capacity as a function of charge-discharge cycle number for charge-discharge cycles of an example hydrothermally treated recycled NCA electrode material.

FIG. 7 shows a graph of specific capacity as a function of charge-discharge cycle number for an example hydrothermally treated recycled after washing and drying.

FIG. 8 shows specific discharge capacities of example NCA electrode materials.

FIG. 9 shows another example method of recycling previously used positive-electrode material of a lithium-ion battery.

FIG. 10 shows a plot of voltage vs. specific capacity for the initial charge-discharge cycle for example oxidative hydrothermally treated NMC 622 electrode materials compared to an untreated standard electrode material.

FIG. 11 shows a plot of specific capacity of the first charge-discharge cycle for example oxidative hydrothermally treated NMC 622 electrode materials compared to an untreated standard electrode material.

FIG. 12 shows a comparison of specific discharge capacity of recovered mixed electrode and the same electrode with oxidative hydrothermal treatment and solid state addition of lithium according to examples.

FIG. 13 is a plot comparing specific capacity of three example atomic layer deposit coated NMC 622 samples.

DETAILED DESCRIPTION

Spent lithium-ion positive-electrode materials may have depleted levels of lithium relative to new materials. Recycling processes for spent lithium-ion positive-electrode materials thus may include relithiation of the spent positive-electrode material. Relithiation may be performed in various manners. For example, relithiation may be performed via hydrothermal treatment of the spent positive-electrode material in an aqueous lithium ion solution, such as a lithium hydroxide solution. The hydrothermally reacted spent electrode material then may be removed from the solution, and sintered to form a recycled electrode material. Examples of such a recycling processes are disclosed in U.S. Pat. No. 9,825,341 entitled RECYCLING POSITIVE-ELECTRODE MATERIAL OF A LITHIUM-ION BATTERY filed Aug. 6, 2015, the entire contents of which are hereby incorporated by reference. Various example relithiation techniques are also described in U.S. Pat. No. 8,846,225, entitled REINTRODUCTION OF LITHIUM INTO RECYCLED BATTERY MATERIALS, the entire contents of which are also hereby incorporated by reference.

However, efficiency of recovery may depend on the type of electrode material being recycled. For example, and without wishing to be bound by theory, during hydrothermal treatment of a nickel-containing positive-electrode material such as a lithium-nickel-cobalt-aluminum (herein referred to as NCA) or lithium-nickel-manganese-cobalt material (NMC), the material may be more sensitive to reducing factors in the environment. As such, nickel may be reduced to a +2 oxidation state, which may impact electrode performance, and lend itself to dissolution from the electrode. Other transition metals may be similarly affected.

Accordingly, examples are disclosed herein that relate to the inclusion of one or more oxidizing agents in a lithium solution during a hydrothermal relithiation treatment. It will be understood that the term “hydrothermal treatment” and the like as used herein may refer to processes that utilize aqueous or non-aqueous solvent-based relithiating solutions at elevated pressure and temperature. Incorporating an oxidizing agent in the hydrothermal treatment step may help to avoid the reduction of metal ions in a positive-electrode material (e.g., an NCA material) by reducing agents, such as carbon, residual electrolyte, binder or other reducing conditions that may be present. Further, the use of an oxidizing agent during hydrothermal treatment may help to avoid subsequent sintering steps in the recycling process, which may help reduce operating costs and also may increase the speed of a recycling process relative to the use of sintering. It will be understood that use of an oxidizing agent as disclosed herein may be incorporated in any other suitable recycling process involving a solvent-based relithiation step, which may or may not include a hydrothermal treatment step.

FIG. 1 illustrates aspects of an example method 10 for recycling previously used positive-electrode material of a lithium-ion battery. The illustrated example is discussed in the context of NCA chemistry, where the positive electrode material includes lithium nickel cobalt aluminum oxide (LiNi_(1-x-y)Co_(x)Al_(y)O₂, e.g., LiNi_(0.8)Co_(0.15)Al_(0.5)O₂) as the electroactive material. Nevertheless, all aspects of the illustrated method are applicable to other positive-electrode chemistries as well. Examples of other positive-electrode materials include, but are not limited to, other materials in which nickel is in a +3 oxidation state, such as nickel manganese cobalt oxide: LiNi_(1-x-y)Co_(x)M_(y)O₂ (M=Al, Mn), (e.g., Li[Ni_((1/3))Co_((1/3))Mn_((1/3))]O₂, with a Ni:Co:Mn ratio of 1:1:1, as well as other Ni:Co:Mn ratios). Further, the disclosed examples may be utilized with electrode materials that do not contain nickel. Examples include, but are not limited to, lithium cobalt oxide lithium iron phosphate and lithium manganese oxide.

In some examples, the positive-electrode material comprises a coating, such as an oxide coating, which may form a barrier between the positive-electrode material and the electrolyte. As electrolytes may be Lewis acids, exposure to the electrolyte material may damage the positive-electrode material and also may reduce long-term capacity. Further, a coating may prevent the positive-electrode material, such as a layered metal oxide, from reacting with dissimilar electrode materials, such as spinel structured battery materials (e.g., lithium magnesium oxide (LMO)) during higher temperature recycling process steps ((e.g. during hydrothermal relithiation or sintering after relithiation). Thus, a coating on a positive-electrode material may provide greater longevity compared to uncoated positive-electrode materials.

In some examples, the positive-electrode material comprises a thin-film coating. Such a coating may be formed in any suitable manner. Examples include, but are not limited to, vapor-phase processes such as atomic layer deposition, as well as solid state methods in which particles are coated with a material of interest and then heated to a suitable temperature to fuse the coating particles. Example coating materials include materials which may coat a particle in a thickness that does not substantially increase ionic and electronic resistance, and thus facilitates lithium ion transport through the coating. As non-limiting examples, a positive-electrode material may be coated with aluminum oxide (Al₂O₃) and/or titanium dioxide (TiO₂). Additionally, a coating may be doped, e.g. with a p-type material, in some examples. While the examples disclosed herein are described in the context of recycling positive-electrode materials, it will be understood that the methods may similarly be applied for recycling negative-electrode materials.

At 12, method 10 includes harvesting a quantity of previously used positive-electrode material. The positive-electrode material may be harvested from any suitable source, such as a lithium-ion battery waste or recycling stream. In other embodiments, the positive-electrode material may be harvested from a generic waste or recycling stream. In some scenarios, the positive-electrode material may be harvested from batteries that have exceeded a recommended shelf life or recommended maximum number of recharge cycles.

The harvesting enacted at 12 may include disassembling one or more lithium-ion batteries and removing the positive-electrode material therein. For example, a lithium-ion battery may include a housing that supports positive and negative exterior terminals and encloses the positive and negative electrodes and non-aqueous electrolyte solution. The positive exterior terminal may be connected via the housing to the positive electrode, while the negative exterior terminal may be connected through the housing to the negative electrode. Depending on the battery configuration, the housing may be breeched by cutting, drilling, and/or prying, to expose the positive- and negative-electrode materials and the electrolyte. In some embodiments, the housing may be breeched under an atmosphere of reduced oxygen and/or humidity. For example, the housing may be breeched under a blanket of nitrogen, argon, or carbon dioxide. Such measures may help to prevent the negative electrode material (which may include metallic lithium or lithium-intercalated carbon) from igniting or releasing an undesirable amount of heat. The term “harvest” may refer to the entirety of, or any sub-part, of the process in which positive-electrode material is removed from batteries and provided to a recycling process. Thus, the term “harvest” and the like may include obtaining the positive-electrode material from another entity that performed the removal of positive-electrode materials from batteries.

In some examples, the harvesting enacted at 12 includes removing the housing and exterior terminals, the non-aqueous electrolyte, and the negative electrode. These components may be recycled separately, if desired. Removing the housing, exterior terminals, non-aqueous electrolyte, and negative electrode leaves behind the positive electrode, which may include a positive-electrode material supported on an aluminum or other metallic and/or conductive foil substrate. The positive-electrode material may also include a significant amount a polymeric binder (e.g., a fluoropolymer or styrene polybutadiene).

In one embodiment, the positive-electrode material may include NCA (LiNi_(x)Co_(y)Al_(z)O₂). In other examples, the positive-electrode material may include NMC (LiNi_(x)Mn_(y)Co_(z)O₂) with various ratios of Ni:Mn:Co (e.g., 1:1:1, 5:3:2, 4:4:2, 6:2:2, 2:6:2, 8:1:1). In yet other examples, the positive-electrode material may include lithium cobalt oxide (LiCoO₂, LCO), lithium manganese oxide (LiMn₂O₄, LMO), lithium nickel manganese cobalt oxide (LiNi_(x)Mn_(y)Co_(z)O₂, NMC), lithium iron phosphate (LiFePO₄, LFP) or lithium titanate (Li₄Ti₅O₁₂). As mentioned above, in the forms typically recovered from waste or recycling streams, these compounds may be lithium-deficient. In other words, these compounds may contain less than the stoichiometric number of lithium ions (Li⁺) compared with the originally manufactured lithium metal oxide material. Accordingly, the recycling method described herein replenishes the lithium content of the recycled positive-electrode materials.

During harvesting, maintaining alkaline pH conditions may help to preserve native cathode materials. For example, the use of a sufficient concentration of lithium hydroxide to make a pH 13 solution may avoid dissolving metals from the cathode materials, and thus may help to keep the cathode materials intact for further processing. Other salts may be used in the solution such as, but not limited to, alkaline earth sulfites, chlorate, peroxide, sulfate, halide, sulfonamide, and mixtures thereof. Other basic compounds may be used to harvest the positive-electrode material such as alkaline earth hydroxides, alkali metal hydroxides, mixtures thereof, ammonium hydroxide and alkyl ammonium hydroxides and mixtures thereof. Lewis base solvents such as pyridine, alkyl amines may also be useful. In some examples, harvesting may be performed using polymeric solutions comprising a solvent and polyethylene oxide, polypropylene oxide, polyethylene imine, copolymers thereof and mixtures thereof. Solvents other than water are also contemplated, including DMSO, alcohols, ionic liquids, and polyether-solutions thereof.

However, as described in more detail below, coated electrodes (e.g. those comprising an oxide coating applied via atomic layer deposition), may tolerate lower pH harvesting conditions than their native congeners. Thus, acidic solutions may be used when harvesting coated positive-electrode materials. Examples include buffered and unbuffered solutions of strong acids and weak acids, such as phosphoric acid/alkali-phosphate, acetic acid/acetate, and sulfuric acid/sulfate. Base buffers may also be used, in some examples, such as ammonium/ammonia, tetralkylammonium/alkylamine.

The use of an acidic rinse or wash step may provide various advantages in some recycling processes. For example, acidic solutions may help to delaminate electrode materials from a current collector structure, e.g. by reacting with an aluminum current collector (Al+H₃O⁺→AlOH+H₂) and/or by decomposing or dissolving polymeric binders. For example, polymethylcellulose, commonly used to bind electrode materials to current collectors, decomposes in low pH solutions. Further, low pH harvesting conditions may be helpful for removing contaminants, including but not limited to various metal-containing materials. For example, iron 3+ is stable below pH 3 and may be useful as an oxidizing agent. The solubility of iron 2+ is relatively high up to pH 7, and thus may be removed by mildly acidic solutions, but may not be soluble in higher pH conditions.

The exposure time for an acid wash may be selected based on the ability of the added layer to protect the bulk particle from dissolution. In various examples, this exposure time may range from seconds to days, and may be impacted by kinetics (e.g., temperature). For example, a low temperature (e.g., 10° C.) pH 4 solution may utilize a longer cleaning treatment than the same solution or a same pH solution at a temperature of 50° C.

In some examples, coated electrodes may have higher hydrophobicity than native electrode materials. This property may assist in floatation separation during harvesting. Suspensions of alumina-coated electrode material particles may be achieved through treatment in a sodium nitrate solution, which may result in improved separation compared to electrode suspensions obtained from native materials. In other examples, positive-electrode material (uncoated and/or coated) may be suspended using a solution comprising a nitrate, a surfactant, a citrate, an alcohol, an ether, pyridine, polyethylene oxide, polyethylene imine, and/or suitable mixtures thereof, as non-limiting examples.

Continuing in FIG. 1, at 14, the supported positive-electrode material is mechanically thrashed in basic medium. This action mechanically separates (e.g., delaminates) the positive-electrode material from the support, partially separates the positive-electrode material from the binder, and breaks each of these components down to a manageable particle size to facilitate subsequent mechanical and chemical processing (vide infra). Thrashing in a basic medium, as opposed to an acidic or neutral media, may lessen the rate of decomposition of the positive-electrode material during the thrashing process for some electrode materials, such as various NMC based materials. In some embodiments, the basic medium may be a liquid medium in which the positive-electrode material is suspended (e.g., an aqueous or non-aqueous solution). In one embodiment, the positive-electrode material is suspended in ambient-temperature water basified with lithium hydroxide (LiOH) to a pH in the range of 11.0 to 11.5. This pH range is basic enough to retard acid hydrolysis of a positive-electrode material, but not so basic as to promote rapid oxidation of the aluminum foil support of the positive-electrode material, which could proliferate aluminum ions through the system. In other embodiments, different bases, solvents, and pH ranges may be used. In particular, the pH range may be adjusted based on the chemical identity of the positive-electrode material (e.g., a more basic pH range for more basic materials, and a less basic range for less basic materials). In one particular embodiment, the desirable pH for rinsing is the same as the pH that the suspended positive-electrode material imparts to deionized water. In some examples, an oxidizing agent, such as LiClO, hydrogen peroxide, lithium peroxide, or any other suitable material, may be included in this solution.

Continuing in FIG. 1, as one non-limiting example, the thrashing of the suspended positive-electrode material may be conducted in a rotating-blade thrashing vessel, which loosely resembles a household blender, but may accommodate samples of one to ten liters. In an example run, 0.5 to 2 kilograms of supported positive-electrode material are thrashed in one liter of basified water for 5 minutes. Naturally, other sample sizes and thrashing times are contemplated as well.

At 16, the various solids deriving from the supported positive-electrode material are collected from the thrashed slurry. The solids may be collected by gravity filtration, pressure filtration, vacuum filtration, and/or centrifugation, for example.

At 18, method 10 may include rinsing the collected solids with a liquid to remove the basic medium used in the thrashing, and to remove any electrolyte (salts and non-aqueous solvent) retained on the supported positive-electrode material prior to thrashing. The rinsing may be performed in the filtration or centrifugation apparatus used for solids collection. In some embodiments, the rinsing liquid comprises an organic solvent. It is desirable that the chosen solvent be partially or fully miscible with water, so that the rinsing process also removes entrained water (from the basic thrashing medium) from the collected solids. It is also desirable that the solvent be recoverable from the rinsings, innocuous to workers and to the environment, and/or suitable for inexpensive disposal compliant with applicable laws. Acetone, ethanol, and some other alcohols are suitable candidates for the rinsing solvent due to their miscibility with water, relatively low toxicity, and ability to dissolve the solvents and salts of the non-aqueous electrolyte (e.g., lithium hexafluophosphate and its decomposition products such as LiF and various phosphates, lithium triflate, ethylene carbonate, diethyl carbonate, etc.). Acetone and ethanol are also potentially recoverable from the rinsings, such as by distillation at reduced pressure.

Acetone has additional attractive properties as a rinse solvent because it is a good solvent for organics and a relatively poor solvent for LiOH. More specifically, various organic compounds (e.g., low molecular-weight polymers and fluoropolymers, plasticizers, etc.) may be present in the binder, which is used to adhere the positive-electrode material to the substrate. Washing with acetone dissolves or solublizes at least some of these components, allowing them to be rinsed away and excluded from subsequent processing. This may increase the purity of the recycled positive-electrode material. In addition, the low solubility of LiOH in acetone may be advantageous in embodiments where the thrashing is performed in water basified with lithium hydroxide (LiOH). Here, a small amount of LiOH remains on the rinsed solids, which may act to suppress acid hydrolysis of the positive-electrode material during the recycling procedure.

In other embodiments, the collected solids may be rinsed in a different organic solvent, or in an aqueous solution having a suitable pH (e.g. an aqueous LiOH solution having a pH of 11.0-11.5). Supercritical carbon dioxide may also be used. Despite the advantages of the rinsing enacted at 18, this step is by no means essential, and may be omitted in some embodiments.

At 20, method 10 includes drying the rinsed solids to remove sorbed water and residual rinse solvent. In the various embodiments here contemplated, the drying may be done in vacuuo, or under a stream of dehumidified (e.g., heated) air or other dry gas, such as nitrogen, argon, or carbon dioxide. In one embodiment, the rinsed solids are dried in a vacuum oven at 140° C.

At 22, method 10 includes mechanically grinding the dried solids. This grinding step may help to reduce the particle size of the positive-electrode material, which may help to improve yield in subsequent sieving. In one non-limiting example, a ball mill may be used for the grinding. In a typical run, a 400-milliliter capacity ball mill is charged with 60 grams of dried solid and 30# agate spheres of 0.5 to 1 centimeter mixed diameter. The mill may be run for 3 to 5 minutes at 50 Hz, for example. It will be noted that the grinding enacted at 22 may undesirably reduce some of the aluminum substrate to a particle size comparable to that of the positive-electrode material, which may reduce the effectiveness of subsequent purification by size selection. Omitting or shortening the grinding step or modifying the ball-mill frequency may increase product purity, at the expense of yield.

At 24, the ground solids are subject to size selection using one or more fine sieves, in order to isolate the positive electrode material from pieces of substrate, binder, and steel filings that may be created by cutting the batteries apart during the harvesting step. In one embodiment, the positive-electrode material selected for further processing is the portion that passes through a 38 to 45 micron sieve, preferably a 38 micron sieve. This fraction, at 22′, is subjected to a second grinding step to further reduce its particle size. Without wishing to be bound by theory, the second grinding step may increase the efficiency of subsequent hydrothermal treatment, to restore the stoichiometric lithium content of the recycled positive-electrode material. Other sequences of grinding and size exclusion are contemplated as well. In some embodiments, a fine filtration step conducted in basified liquid medium may be used in lieu of sieving.

At 26, method 10 includes removing an amount of carbon from the solids prior to hydrothermal treatment. For example, carbon may be removed by heating the solids at sufficient temperature to burn out the carbon. Removal of carbon also may be accomplished by density methods commonly employed in the mining industry through slurries or with liquids having an intermediate density between carbon, carbon graphite (2.2 grams/cc) and the lithium metal oxides (typically 3 grams/cc). Removing carbon may help to prevent decomposition of the positive-electrode material during the hydrothermal treatment step. However, it is noted that practice of the disclosed example processes with carbon graphite present does not appear to impede relithiation of the positive electrode material. It will be understood that any other suitable method for removing carbon may be utilized, and the pre-removal of carbon is optional.

In embodiments wherein the positive-electrode material is coated, method 10 may include further rinsing in neutral-to-acidic conditions prior to and/or following hydrothermal treatment. While rinsing in a neutral or acidic solution may damage uncoated positive-electrode materials, a coated positive-electrode material may withstand some duration of rinsing in a neutral or acidic solution. In some examples, an acidic rinse may comprise rinsing for 10-30 seconds in a solution having a pH of 3 to 6.9. In other examples, other suitable conditions may be used. It will be understood that rinsing a coated positive-electrode material in a neutral-to-acidic solution is optional and may take place at any stage in processing, for example, before and/or after hydrothermal treatment.

At 28, the twice ground solids are relithiated, for example, via hydrothermal treatment in in an autoclave with concentrated or supersaturated aqueous LiOH and an oxidizing agent. In other examples, other sources of lithium ions may be used. Examples include lithium fluoride, lithium triflate, lithium sulfate, lithium sulfite, and/or any other lithium salt in which the anion is the conjugate base of a strong acid or a reasonably strong acid, such as hydrofluoric acid (HF). Such salts may be soluble in polar solvents such as water, methanol, and DMSO. Solvents other than water are also contemplated for the solvo-thermal reaction, including DMSO, alcohols, ionic liquids, and polyether-solutions thereof.

In some examples, ethylene carbonate, propylene carbonate, and/or any other suitable frothing agent may be included in a solvo-thermal reaction solution. Such materials may assist in floating carbonaceous materials, including graphite and carbon black, from the mixture during hydrothermal treatment. In contrast, density methods that use solvents of intermediate density have been found to remove graphite from a positive/negative electrode mixture, but not remove carbon black and remaining binder material. Here, the hydrothermal process removes the binder by reaction at high pH and floats all carbonaceous materials such as graphite and carbon black, leaving the positive electrode in high purity, e.g. 95%. As another example, the positive-electrode material may be relithiated via a fluidized bed process, where the reactant solution of LiOH (and/or lithium sulfate, lithium hydroxide, lithium peroxide, lithium oxide, lithium chloride, lithium fluoride, lithium bromide, lithium iodide, lithium citrate, lithium oxalate, lithium nitrate, lithium triflate, lithium-ionic liquids and lithium molten salts) and the oxidizing agent is passed through the positive-electrode material residing in the fluidized bed. As yet another example, relithiation may be performed via a solid-state reaction using a lithium salt, e.g. LiOH, Li₂O, or Li₂CO₃. Relithiation may help to restore the stoichiometric lithium content of the positive electrode material, for example, by displacing any foreign cations (e.g., impurities) or misplaced cations (e.g., nickel ions that may migrate to lithium sites in a lattice) that may be present. In one embodiment of hydrothermal treatment, one liter of 24% LiOH may be used for each kilogram of positive-electrode material. It will be noted that this concentration of LiOH exceeds saturation at typical ambient temperatures. The contents of the autoclave may be ramped from ambient temperature of 250 to 275° C. at a rate of 5° C. per minute, and maintained at that temperature for 12 to 14 hours. Alternatively, heating to 250° C. and subsequent cooling to room temperature also has been found to be effective. Higher temperatures are found to reduce yield, potentially by promoting undesirable side reactions involving the residual binder. In other examples, any other suitable solution of lithium ions than a lithium hydroxide solution may be used in the relithiation step, and any other suitable processing conditions may be used.

As described above, the use of an oxidizing agent may help to avoid reduction of metal ions during the relithiation process. Without wishing to be bound by theory, various conditions that may be encountered in a hydrothermal or other relithiation process may tend to reduce metal ions in the positive-electrode material. For example, deoxygenation in NCA or NMC materials occur by the reaction LiNiO₂→Li_((1-x))NiO_((2-y))+xLi⁺+yO₂ ⁻ (oxygen loss)→NiO. Thus, incorporating an oxidizing agent may help to avoid such metal ion reduction. Addition of an oxidizing agent during relithiation (e.g. hydrothermal treatment) also may obviate the need for any oxidizing steps downstream, such as sintering under oxygen or other oxidizing atmosphere, thus simplifying the recycling process.

Any suitable oxidizing agent may be used in the relithiation solution. Examples include, but are not limited to, peroxides such as hydrogen peroxide, lithium peroxide, sodium peroxide, benzoyl peroxide, ozone, oxygen, permanganates, chorine, hypochlorites, chlorates, perchlorates, percarbonates, perborates, iron, fluorine, sulfite, beryllium fluoride, boron fluoride, carbonate, nitrate, arsonate, phosphate, antimonite, tellurate, iodate, TiCl₆, SnCl₆, germanium fluoride, platinum hexchloride, chromate, molybdate, or any compound having an oxygen atom capable of accepting an extra electron. In some examples, hydrogen fluoride may be added along with the oxidizing agent, as fluorination may help to further stabilize the desired oxidation state(s) of the nickel. In some examples, it may be desirable to remove byproducts of oxidation. For example, Fe³⁺ oxidizing agent may produce an Fe²⁺ species that would not be desirable in the end product.

Additionally, in some examples, the relithiation solution may comprise dilute nickel. For example, hydrothermal relithiation solution may be reused between batches numerous times. It has been found that the hydrothermal relithiation solution comprises dissolved Ni²⁺, and that the concentration of the dissolved nickel appears to remain at a relatively consistent concentration from batch to batch. Thus, having some dilute nickel in the hydrothermal solution, whether added prior to relithiation or retained from previous batches using the same solution, may help to retain nickel in the electrode material lattice. Further, in some examples, it has been found that relithiating in a hydrothermal relithiation solution comprising dilute transition metal ions may increase a metal content in an electrode material. For example, nickel content of a NMC electrode 6:2:2 material lattice may increase following hydrothermal treatment with nickel ions present in the hydrothermal relithiation solution (e.g., a 0.02-1M concentration of Ni2+, or other suitable concentration). This may help to reduce defect sites in the electrode material lattice, and also may increase the content of electrochemically active metals, which may improve capacity or voltage stability. In other examples, other transition metal ions (e.g., cobalt) may be present in the relithiation solution, depending upon the electrode material. In such a process, external manganese addition via the relithiation solution may be very limited due to low solubility. In some examples, however, such as with lower pH treatments, manganese may be similarly reintroduced in the electrode material lattice via mass action from a saturated solution.

At 16′ the cooled, hydrothermally treated solids are collected, and at 30 the solids are rinsed to remove excess LiOH, Li₂O, and/or other lithium salts, which may help to avoid absorption of water at a future storage or manufacturing stage. Some materials may potentially be sensitive to the manner of rinsing at this stage of the process. For example, as mentioned above, neutral-to-acidic conditions may impact the electrochemical properties of uncoated positive-electrode material (e.g., capacity and current capability). Without wishing to be bound by theory, sensitivity to acid hydrolysis may be higher at this stage than earlier stages for some positive-electrode materials, because the binder has been mostly eliminated. Accordingly, the collected solids may be rinsed with water basified by LiOH to a pH in the same range as used in rinsing step 18 (e.g., pH 11.0 to 13.5 for NCA). Ammonium hydroxide, a tetraalkyl ammonium hydroxide (e.g. TBAOH) and other basic media (e.g., alkaline metal and alkaline earth hydroxides, alkyl ammonium hydroxides, and/or organic Lewis bases) may additionally or alternatively be used for rinsing. Alternatively, the collected solids may be rinsed with less basic or even deionized water, while, at 32, the pH of the filtrate is continuously monitored. Other suitable solvents for rinsing may include, but are not limited to, nonaqueous solvents such as liquid carbon dioxide, supercritical carbon dioxide, methanol, ethanol, isopropol alcohol, t-butanol, n-butanol, glycol, polyethelene glycol, bromoform, di-bromomethane, bromal, tetraboro-methane, bromine, di-bromoethane; solutions of ammonium metatungstate, sodium polytungstate, and potassium tetraiodomercurate(II), and/or solutions thereof.

Rinsing, at 30, may be ended when the pH of the filtrate falls within a desired range. For example, for a 500-gram batch of positive-electrode material, a total of 4 liters of wash water may be used, prior to the pH dropping into the target range. In another embodiment, 4 liters of aqueous LiOH within a desired pH range may be used. As described above, a coated positive-electrode material may exhibit less sensitivity to acid hydrolysis at this rinsing stage compared to an uncoated positive-electrode material, and thus may be rinsed in neutral-to-acidic conditions, in some examples.

At 20′, method 10 includes drying the rinsed, hydrothermally treated solids in a vacuum at 150 to 160° C. It will be understood that any suitable method may be used to dry the rinsed, hydrothermally treated solids, in other examples. At 22″, method 10 may include grinding the solids for a third time, which may help to provide a particle size suitable for application on a new positive-electrode support. In some examples, method 10 may include recoating the positive-electrode material. For example, coating on a positive-electrode material may be depleted during the recycling methods described herein, and thus the positive-electrode material may be recoated. The positive-electrode material may be re-coated in any suitable manner, such as via atomic layer deposition.

The above-described processes may be implemented as continuous flow processes or as a batch processes. For example, a continuous flow system may utilize a screw feed system, such as a twin-screw extruder, as a reactor to achieve similar pressures and temperatures as used in a batch hydrothermal treatment. Further, a screw feed apparatus may be used to introduce harvested electrode material to a reaction zone in which the reaction liquor is pumped over a slurry or other concentrated mass of harvested electrode material. Additionally, a screw feed apparatus may include rinsing stages incorporated into the apparatus.

Experiments reveal that NCA harvested from hydrothermal treatment without an oxidizing agent results in apparent decomposition of NCA during hydrothermal treatment, as the harvested powder product exhibits a brown color indicative of decomposition. FIG. 2 shows a plot of x-ray powder diffraction patterns for example NCA electrode materials including a standard untreated and un-depleted NCA, a clean (e.g., rinsed) recycled NCA hydrothermally treated with an oxidizing agent, a pre-washed (e.g., pre-rinsed) recycled NCA hydrothermally treated with an oxidizing agent, and a recycled NCA that was hydrothermally treated without an oxidizing agent. The hydrothermal treatment was performed using 2 g NCA+75 mL total solution of 4M LiOH and 5 mL of 30% H₂O₂. The reaction was carried out at 250° C. in a stirred autoclave for 9 hours. The resulting product was removed from the reactor and collected in a centrifuge. Powder x-ray diffraction data from this sample is shown in FIG. 2 as “pre-washed hydrothermal NCA with oxidizing agent.” The sample was then washed 3× with a dilute solution of LiOH (pH of 13.3) and centrifuged. The powder x-ray diffraction pattern for this sample is shown in FIG. 2 as “clean hydrothermal NCA with oxidizing agent.” The NCA samples hydrothermally treated with an oxidizing agent produced black colored powder having little to no browning, indicating a more stable crystalline material without decomposition. In contrast, the recycled NCA hydrothermally treated under similar conditions but without an oxidizing agent shows entirely different diffraction peaks in the powder diffraction pattern, indicating that the material was converted to a different phase or phases than the form used as electrodes. The hydrothermal reactions without oxidizing agent produce lithium carbonate, and decompose the layered character of the NCA indicated by the loss of the (003) reflection at 19° two-theta. Oxidizing conditions conserve the layered, electrochemically active material and suppress the formation of lithium carbonate.

As mentioned above, the observed decomposition of NCA may be due to the sensitivity of the NCA material in a reducing environment, as the nickel in NCA is present in a +3 oxidation state. Such an oxidation state may be vulnerable to decomposition into 2+ and 4+ states, which may lead to instabilities, for example via the Jahn-Teller effect. Ni²⁺ is soluble in solutions and organic solvents, which is evident in the presence of an apple green appearance of wash solutions and hydrothermal fluid. Using dilute Ni²⁺ (i.e. mg/mL, or reuse of previous hydrothermal bath fluid) in the hydrothermal bath mixture may impact the electrochemical activity of the recycled product, however, the comparison is not complete. Ni³⁺ and Ni⁴⁺ moieties are not soluble in solution. Then, the oxidizing agent may help to maintain the nickel in a +3 oxidation state and avoid such defects, as well as other possible issues, such as phase separations due to the mixed oxidation states.

FIG. 3 is a plot showing specific capacity of the first charge-discharge cycle for an example oxidative hydrothermally treated NCA electrode material compared to an untreated NCA standard electrode material. The treated NCA electrode material was not recovered from a battery, but instead was an unused material subjected to hydrothermal treatment utilizing hydrogen peroxide as an oxidizing agent. The above described hydrothermal treatment process was used, and the black solid was dried under a vacuum at 125° C. and built into small button cells for electrochemical capacity evaluation. The plot shows that the baseline charge and discharge capacities of the untreated NCA standard electrode material are less than that of the treated material. Thus, treated NCA material exhibits increased capacity and higher voltage profile on discharge, indicating that the treated NCA material may have improved performance compared to the untreated standard NCA material.

FIG. 4 is plot of x-ray powder diffraction (XRD) patterns comparing example NCA electrode materials including a standard NCA, a recycled NCA hydrothermally treated with an oxidizing agent, and a recycled NCA hydrothermally treated with an oxidizing agent and also calcined afterward. The above described hydrothermal process was used, again with hydrogen peroxide as the oxidizing agent. The hydrothermal treatment of harvested NCA material resulted in a black colored powder, with the XRD pattern shown at the bottom of the plot of FIG. 4 (“Hydrothermal NCA with oxidizing agent”). Calcination was then performed by placing the NCA material in a crucible and heating under oxygen (1 torr) at 800° C. for nine hours. The resulting material produced the XRD pattern shown in the middle of the plot (“Post-calcination hydrothermal NCA with oxidizing agent”). As shown, the XRD pattern of the calcined material shows more similar diffraction peaks to that of the standard NCA material, compared to the XRD pattern of the hydrothermally treated material without calcination. The results indicate that using a calcination process in addition to hydrothermal treatment with an oxidizing agent may further improve the recovered material. The reflection at two-theta of 21.5 is due to lithium carbonate, which is an intermediate produced in the hydrothermal process.

FIG. 5 is a graph showing specific capacity as a function of charge-discharge cycle number for a test cell of an example untreated NCA standard electrode material, and FIG. 6 shows specific capacity as a function of charge-discharge cycle number for test cell of an example oxidative hydrothermally treated NCA electrode material. Results show that the treated cell maintains higher capacity over time and use, although it may reduce efficiency (lower discharge-to-charge ratios). FIG. 7 shows specific capacity as a function of charge-discharge cycle number for a test cell of a NCA material after washing with deionized water and vacuum drying afterwards. The plot of FIG. 6 shows higher capacity and efficiency for the washed NCA material.

FIG. 8 shows specific discharge capacities of example NCA electrode materials, showing a sample NCA material harvested from a cell and the NCA material after oxidative hydrothermal treatment and calcination in comparison to a standard NCA material after calcination. The plot of FIG. 8 shows that the discharge capacity of the harvested NCA material is less than that of the recycled treated material, indicating that the oxidative hydrothermal treatment followed by calcination treatment may improve the capacity of recycled NCA materials.

FIG. 9 shows another example method 90 for recycling previously used positive-electrode material of a lithium-ion battery. Method 90 includes, at 91, discharging the battery to a nominal voltage (i.e. less than 0.1) or short circuit. This may be accomplished through resistors, solution, or solution with a discharge shuttle.

At 92, method 90 includes opening the cell through physical means such as slitting, shredding, use of a blender, high-pressure fluid cutting, and/or disassembling through manual or machine-operated methods. The disassembly may occur along with a high pH solution or organic solvent, and also may occur separately with subsequent transfer of material into the solvent/solution. Example solvents include n-methyl pyrolidone, di-chloromethane, and alcohols (methanol, ethanol, t-butyl alcohol, isopropyl alcohol). Example solutions which are basic include lithium hydroxide or other pH increasing moieties, along with soaps or other emulsifiers. During the thrashing portion of the disassembly process, a significant fraction of carbon material may float in the mixture and thus may be removed by skimming.

Method 90 includes, at 93, using a mesh, decanting, centrifuging or filtering to separate the solid electrode materials from the cell parts. The solid electrode material may be purely positive-electrode material (lithium metal oxide) or positive-electrode material mixed with negative electrode material such as carbon or silicon. The collected solid mixture is commonly referred to as “black mass” in the recycling industry, but referred to as harvested material herein. Harvested material may be de-watered to a solid sludge, or dried to a powder. In some examples, the positive-electrode material comprises 1 to 18-micron sized particles having metal oxide coatings. At 94, the harvested material is placed into an autoclave for hydrothermal treatment. An example is 2 g of harvested material, 75 mL of 4M or greater LiOH solution (e.g. 90 g solution/75 mL) and an oxidizing agent, e.g. 2-4 mL of H₂O₂. Other suitable oxidizing agents include LiClO₄ and those listed above. The mixture is then sealed and heated to 250° C. over two hours, and allowed to naturally cool to room temperature. The total process time may range from 3-4 hours in some examples.

At 95, method 90 includes opening the autoclave and skimming off any floating carbon rich material. The autoclave decomposes binders, which release intimate mixtures of carbon and lithium metal oxide. The carbon remains suspended or floating shortly after reaction (e.g., 15 min). At 96, the autoclave reaction solution is recaptured for reuse in subsequent reactions. The solution may have an apple-green hue after treatment with a nickel containing electrode, which may be attributed to Ni²⁺ ions in solution. Reuse of the solution from step 94 may produce the same, positive results for recycling electrode materials. Solution reuse has been tested 12 times with different electrode materials with similar positive results. Note that reuse may include adding LiOH to reach a density of 90 g solution/75 mL along with adding the oxidizing agent. Added LiOH is consumed in relithiation, or diluted in the rinse. Recapturing the autoclave solution may include, at 97, rinsing the treated electrode material with a basic pH solution. In some examples, such as when the positive-electrode material is coated, the treated electrode material may additionally or alternatively be rinsed with a neutral-to-acidic solution. During or after the rinse, dense liquids may be used to further separate carbons from the lithium metal oxides because the binders have been removed from the electrode mixture.

At 98, method 90 may include drying the product prior to calcination, or in the process of calcination through an evaporative step. At 99, the product may be heated, sintered, or calcined at, for example, temperatures from 300° C. to 1000° C. to reorder the crystal lattice of the lithium metal oxide and vaporize any remaining organic materials. Coated materials may allow for lower temperature processing than noncoated materials. For example, product comprising coated material may be heated, sintered, or calcinated at temperatures from 100° C. to 1000° C. The process optionally may include an oxygen rich atmosphere. Examples disclosed herein were heated to 940° C. for the nickel rich layered metal oxides, and 300° C. for lithium cobalt oxide (nickel-dilute layered metal oxides). Further, as shown at 100, an additional quantity of a lithium ion source, such as lithium carbonate, lithium hydroxide, lithium sulfate, lithium oxide, and/or lithium acetate, as examples, may be added to further help reintroduce lithium into the metal oxide lattice. It has been found that the addition of lithium carbonate to the sample during calcination may result in increased capacity of the end product, as described in more detail below. Performing the calcination with additional lithium ions after the hydrothermal treatment (hydrothermal treatment may remove substantially all binder from the material) may avoid problems posed by binder materials in the calcination, as binders can decompose and form LiF with the lithium ions present, which may result in less reintercalation of Li ions into the metal oxide lattice.

In an example experiment utilizing the process of FIG. 9 to hydrothermally treat NCA electrode material, the treated electrode materials were then constructed into electrodes with carbon black, and binder (polyvinylidene di-fluoride, PVDF). An example electrode mixture may include 92% active electrode material, 4% binder, and 4% carbon black. The test electrode was made using a press pellet and typically has a mass of 15 mg. These electrodes were sealed into button cells against lithium electrodes with a commercial lithium-ion electrolyte. The testing was accomplished on Maccor or Arbin cycling instruments using current densities between 0.1-2.5 mA/cm², and is herein referred to as C-rate in which 0.05-1 C is 20 hours−1 hour for discharge. Standard electrode materials were used to compare the recycled electrode materials.

FIG. 10 shows a plot of voltage vs. specific capacity for the initial charge-discharge cycle for example oxidative hydrothermally treated NMC 622 electrode materials compared to an untreated standard electrode material. Table 1 shows the autoclave conditions used for each treatment shown. The NMC 622 cells were faded to 80% of their original capacity and processed. The use of oxidizing agents in the autoclave is shown to return high-specific capacity to spent electrodes. Hydrogen peroxide may be a suitably effective agent, due to the reduction step that occurs in order to liberate oxygen. Hydrogen peroxide may be assisting the reintroduction of lithium into metal oxide structures (a reducing step). The oxidizing agent may be stabilizing Ni³⁺ states in the solid (as described above).

FIG. 11 shows a plot of specific capacity of the first charge-discharge cycle for example oxidative hydrothermally treated NMC 622 electrode materials compared to an untreated standard electrode material. FIG. 11 shows that recycled NMC 622 produced with oxidizing agents were able to demonstrate improved rate capability and higher specific capacity over standard materials.

TABLE 1 Autoclave conditions for Treatments 1, 2 and 3 in FIG. 10 Autoclave condition Treatment 1 LiOH autoclave (all other steps are equal) Treatment 2 LiOH autoclave with LiClO₄ (1 gram) Treatment 3 LiOH autoclave with H₂O₂

Table 2 summarizes specific capacities as a function of lithium-ion chemistry, harvest method, and autoclave process. The “harvest solvent” column designates whether each sample was harvested in NMP or water. The Li-ion chemistries represent layered metal oxides with increasing nickel content. The use of oxidizing agents may improve recycling of nickel rich NMCs and NCA materials. Table 2 is limited to layered materials. The names of the NMC samples reflect the stoichiometries of the samples (e.g., NMC (111) comprises nickel, manganese and cobalt in 1:1:1 proportions).

TABLE 2 Summary of capacity for layered metal oxide electrodes and process conditions. Harvested Oxidizer & Material Hydrothermal Hydrothermal Specific Processed Processed Harvest Capacity Material Material Chemistry State of Health Solvent mAh/g mAh/g mAh/g LCO Standard NMP 140 140-150 140-150 Scrap Material N/A — — — New Cell NMP  90-100 140-150 140-150 Used Cell > 20% NMP 60-90 140-150 140-150 loss LCO Standard Deionized 140 140-150 140-150 water Scrap Material N/A — — — New Cell Deionized  90-100 140-150 140-150 water Used Cell > 20% Deionized 60-90 140-150 140-150 loss water LCO/Titania Standard N/A 150 est — — Scrap Material N/A — — — New Cell NMP  90-100 140-150 140-150 Used Cell > 20% NMP 60-90 140-150 140-150 loss LCO/Titania Standard N/A 150 est N/A — Scrap Material N/A — — — New Cell Basic  90-100 140-150 140-150 solution Used Cell > 20% Basic 60-90 140-150 140-150 loss solution NMC 523 Standard NMP 155 155 155 Scrap Material NMP 155 155 155 New Cell NMP 120 155 155 Used Cell > 20% NMP 80-90 153 153 loss NMC 523 Standard Basic 155 155 155 solution Scrap Material Basic 155 155 155 solution New Cell Basic 120 155 155 solution Used Cell > 20% Basic 80-90 153 153 loss solution NMC 622 Standard NMP 160 160 160 Scrap Material NMP 160 160 160 New Cell NMP — — — Used Cell > 20% NMP 20-40  40 160 loss NMC 622 Standard Basic 160 160 160 solution Scrap Material Basic — — — solution New Cell Basic 120 160 160 solution Used Cell > 20% Basic 20-40  40 160 loss solution ALD New material, Basic 140 170 N/A NMC622 Air Exposed solution NMC622 Untreated, Air Basic 120 140 N/A Exposed solution NCA Standard NMP 190 190 190 Scrap Material N/A — — — New Cell NMP 170 190 190 Used Cell > 20% NMP 20-40  40 160 loss NCA Standard Basic 190 190 190 solution Scrap Material Basic — — — solution New Cell Basic 170 190 190 solution Used Cell > 20% Basic 20-40  40 160 loss solution

FIG. 12 shows a comparison of specific discharge capacity of recovered mixed electrode comprising different types of cathode materials (spinel materials (LiMn₂O₄) and lithium nickel cobalt oxide materials), and the same mixed electrode after oxidative hydrothermal treatment. The oxidative treatment described above improved the specific capacity of spent Li-ion electrode mixed materials. For this example, the materials were first harvested and then tested. The specific capacity for the harvested but untreated materials corresponds to the left-most plot 1202 in FIG. 12. Next, some material was removed from the sample and subjected to a solid-state calcination in the presence of lithium carbonate. The specific capacity of this sample is shown at 1204. Next, the sample that was not initially calcinated was treated hydrothermally, as described above. Some of this hydrothermally treated sample was calcinated without additional lithium ions. The specific capacity of this sample after hydrothermal treatment is shown at 1206. Another of the hydrothermally treated material was calcinated with additional lithium carbonate, added in an amount equivalent to approximately 30 mAh of additional specific capacity. The specific capacity of this sample is shown at 1208. Without wishing to be bound by theory, it is believed that the hydrothermal treatment process removes binder material from the electrode material mixture, and therefore avoids problems with side reactions with fluoride and possibly other species during calcination.

As described above, atomic layer deposition (ALD) of material on the surface of a metal oxide, carbon, or silicon particle may produce an electrode with improved properties. Examples include improved resistance to electrolyte reactions, inhibition of metal extraction from the electrode, protection of the electrode against interaction with air (oxygen, moisture, carbon dioxide or other gases), and inhibition of reaction between dissimilar electrode materials such as spinel and layered metal oxides, for example. With regard to recycling or treatment of used and/or abused electrode materials, ALD can be a method to design on the atomic scale for direct recycling methods taught herein.

The direct recyclability of atomic layer deposition (ALD) materials is demonstrated in FIG. 13 and Table 2, above. An ALD-NMC capacity may be approximately 170 mAh/g, in some examples. After exposure to air for several days, the capacity may drop to 160 mAh/g. Such capacity loss may result from exposure to atmospheric water, carbon dioxide, and oxygen, for example. Without wishing to be bound to theory, air exposure may alter the oxide surface chemistry to produce Ni²⁺, which may impede lithium transport. As shown in FIG. 13, treatment of the abused cathode material, with hydrothermal methods disclosed herein, resulted in materials with a normal specific capacity. Both ALD-NMC and NMC may behave this way, and the capacity may be reinstated after hydrothermal treatment and heating. Further, while the (uncoated) NMC may require sintering at temperatures ranging from 600° C.-900° C., the ALD-NMC sample was heated only to 300° C. In other examples, coated positive-electrode materials were reinstated after hydrothermal treatment and heating to 100° C. This comparatively lower temperature recycling process may be a result of the ALD treatment of the cathode material. Such ALD coating may leverage recycling process parameters, such as pH tolerance of electrodes during rinsing at any stage. For NCA, which may be sensitive to water exposure, ALD treatment may enhance the ability for recycling such material in aqueous media. As yet another potential advantage, ALD coating may leverage recycle processing parameters for mixed electrode materials that otherwise may directly react with one another at low temperatures (for example, 50°-500° C.).

Some of the process steps described and/or illustrated herein may, in some embodiments, be omitted without departing from the scope of this disclosure, and/or additional steps may be used. Likewise, the indicated sequence of the process steps may not always be required to achieve the intended results, but is provided for ease of illustration and description. One or more of the illustrated actions, functions, or operations may be performed repeatedly, depending on the particular strategy being used. It will be understood that the articles, systems, and methods described hereinabove are embodiments of this disclosure—non-limiting examples for which numerous variations and extensions are contemplated as well. This disclosure also includes all novel and non-obvious combinations and sub-combinations of the above articles, systems, and methods, and any and all equivalents thereof. 

1. A method for processing coated positive-electrode material of a lithium battery, the method comprising: separating the coated positive-electrode material from an electrode support by agitating the coated positive-electrode material and the electrode support in a solution; and forming a suspension of the coated positive-electrode material.
 2. The method of claim 1, wherein agitating comprises agitating the coated positive-electrode material and the electrode support in a basic solution comprising an oxidizing agent.
 3. The method of claim 1, wherein agitating comprises agitating the coated positive-electrode material and the electrode support in a basic solution.
 4. The method of claim 1, wherein agitating comprises agitating the coated positive-electrode material and the electrode support in an acidic solution with an oxidizing agent.
 5. The method of claim 1, wherein agitating comprises agitating the coated positive-electrode material and the electrode support in an acidic solution.
 6. The method of claim 1, wherein forming a suspension comprises forming a suspension comprising a solution of one or more of a nitrate, a surfactant, a citrate, an alcohol, an ether, pyridine, polyethylene oxide, and polyethylene imine.
 7. A method of recycling a coated positive-electrode material of a lithium-ion battery the method comprising: relithiating the coated positive-electrode material in a solution comprising lithium ions; and after relithiating, separating the coated positive-electrode material from the solution.
 8. The method of claim 7, wherein relithiating comprises relithiating via a solvo-thermal reaction, and wherein a solvent of the solvo-thermal reaction comprises one or more of water, an ionic liquid, DMSO, an alcohol, and a solution comprising polyether.
 9. The method of claim 7, wherein the solution for relithiating comprises ethylene carbonate, and wherein the ethylene carbonate floats carbonaceous materials from the solution.
 10. The method of claim 7, wherein the lithium ions in the solution are soluble lithium ions, the soluble lithium ions comprising one or more of lithium fluoride, lithium triflate, lithium sulfate, and lithium sulfite.
 11. The method of claim 7, wherein the solution comprises an oxidizing agent, the oxidizing agent comprising one or more of oxygen, a peroxide, a permanganate, a nitrate, a sulfite, a carbonate, and a phosphate.
 12. The method of claim 7, wherein relithiating comprises heating the coated positive-electrode material in the solution under pressure in an autoclave.
 13. The method of claim 7, further comprising reusing the solution for relithiating in a subsequent reaction or in a continuous feed.
 14. The method of claim 7, further comprising, after relithiating, removing impurities from the coated positive-electrode material by rinsing the coated positive-electrode material.
 15. The method of claim 14, wherein rinsing comprises one or more of: rinsing with one or more of ammonium hydroxide, TBAOH, and methanol; and rinsing with a nonaqueous solvent comprising one or more of methanol, ethanol, isopropol alcohol, t-butanol, n-butanol, glycol, polyethelene glycol, bromoform, di-bromomethane, bromal, tetraboro-methane, bromine, di-bromoethane; solutions of ammonium metatungstate, sodium polytungstate, and potassium tetraiodomercurate(II).
 16. The method of claim 14, further comprising, after rinsing, drying the coated positive-electrode material in a vacuum.
 17. The method of claim 7, wherein separating the coated positive-electrode material from the solution comprises forming a suspension of the coated positive-electrode material utilizing a solution comprising one or more of a nitrate, a surfactant, a citrate, an alcohol, an ether, pyridine, polyethylene oxide, and/or polyethylene imine.
 18. The method of claim 17, wherein the coated positive-electrode material comprises a spinel material, the method further comprising, after separating the coated positive-electrode material, heating the coated positive-electrode material at a temperature of 100° C.-900° C.
 19. The method of claim 7, wherein relithiating comprises utilizing a screw-feed system, further comprising one or more rinsing stages within the screw-feed system to remove excess reagents and impurities.
 20. A method of recycling a coated positive-electrode material of a lithium-ion battery the method comprising: relithiating the coated positive-electrode material in a solution comprising a lithium source and an oxidizing agent; and after relithiating, separating the coated positive-electrode material from the solution. 